Optical signal demultiplexing device and optical signal demultiplexing method

ABSTRACT

An optical signal demultiplexing device includes a demultiplexing unit that receives an optical signal multiplexed by an optical time-division system and a synchronization pattern, and demultiplexes the optical signal based on the synchronization pattern. The optical signal demultiplexing device also includes a pulse-width increasing unit that makes optical signals demultiplexed by the demultiplexing unit generate chirp, and increases the pulse widths of the optical signals generating the chirp by passing the optical signals through a wavelength dispersion medium.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an optical signal demultiplexing devicethat multiply demultiplexes an optical signal multiplexed by an opticaltime-division system.

2. Description of the Related Art

In recent years, in an optical fiber communication system, OTDM (OpticalTime Division Multiplex) for time-division multiplexing optical signalsdirectly in the state of light is being studied. According to this OTDM,when multiplexing optical signals, the optical signals are multiplexedat a timing assigned beforehand. When demultiplexing the multiplexedoptical signal, multiplexed light is demultiplexed at a timing assignedbeforehand. By multiplexing and demultiplexing the optical signalsdirectly in the state of light by using the OTDM, a large capacitance ofan efficient and economic network can be achieved.

Japanese Patent Application Laid-open No. H7-221708 discloses atechnique of compensating for a delay of an optical signal generated byan optical path difference within a node, using dispersion dependency ofan optical fiber on a wavelength, when the optical signal passes withineach node that constitutes an optical fiber communication system,thereby achieving a precise synchronization of the optical signalconcerning the optical fiber communication system.

However, according to the conventional technique described above,because the optical signal of each channel needs to be multiplexed anddemultiplexed at a specified timing in the OTDM, there has been aproblem in that high-level process cannot be performed in the state ofthe optical signal (for example, according to the conventionaltechnique, only a path change can be performed in the state of theoptical signal).

To progress the use of light in the network, the cost of processing anoptical signal directly in the state of light needs to be lower than thecost of converting an optical signal into an electric signal. At thesame time, the process of the optical signal in the state of light needsto be diverse like the process of the electric signal. That is, inprocessing light directly in the state of light, when only the path canbe changed, it is considered unlikely that the use of optical signals inthe network becomes popular by replacing the electric signals that canbe flexibly processed.

In other words, when the optical signal is processed directly in thestate of light, it is considerably important that light can achievehigh-level process that the electric signal can achieve.

SUMMARY OF THE INVENTION

It is an object of the present invention to at least partially solve theproblems in the conventional technology.

According to an aspect of the present invention, an optical signaldemultiplexing device includes a demultiplexing unit that receives anoptical signal multiplexed by an optical time-division system and asynchronization pattern, and demultiplexes the optical signal based onthe synchronization pattern; and a pulse-width increasing unit thatmakes optical signals demultiplexed by the demultiplexing unit generatechirp, and increases the pulse widths of the optical signals generatingthe chirp by passing the optical signals through a wavelength dispersionmedium.

According to another aspect of the present invention, an optical signaldemultiplexing method includes receiving an optical signal multiplexedby an optical time-division system and a synchronization pattern, anddemultiplexing the optical signal based on the synchronization pattern;making the demultiplexed optical signals generate chirp; and increasingthe pulse widths of the optical signals generating the chirp by passingthe optical signals through a wavelength dispersion medium.

The above and other objects, features, advantages and technical andindustrial significance of this invention will be better understood byreading the following detailed description of presently preferredembodiments of the invention, when considered in connection with theaccompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an explanatory diagram for explaining a network configurationof an OTDM which a conventional optical multiplexing device and aconventional optical demultiplexing device cannot achieve;

FIG. 2 is a functional block diagram of a configuration of an opticaldemultiplexing device according to a first embodiment;

FIG. 3 is a functional block diagram of a configuration of apulse-length increasing unit;

FIG. 4 is a functional block diagram (1) of a configuration of apulse-length increasing unit using a wavelength conversion element;

FIG. 5 is a functional block diagram (2) of a configuration of thepulse-length increasing unit using the wavelength conversion element;

FIG. 6 is a time chart of a state that an OTDM- multiplexed opticalsignal is demultiplexed by an optical demultiplexing device;

FIG. 7 is a functional block diagram of a configuration of an opticaldemultiplexing device according to a second embodiment;

FIG. 8 is a functional block diagram of a configuration of an opticaldemultiplexing device according to a third embodiment;

FIG. 9 is a functional block diagram of a configuration of an opticalmultiplexing device that executes a byte-interleaved multiplexing;

FIG. 10 is a time chart concerning an optical signal of the opticalmultiplexing device shown in FIG. 9;

FIG. 11 is a functional block diagram of a configuration of an opticalsignal device that multiplexes overhead data with a low-speed signal;

FIG. 12 is a time chart concerning an optical signal of the opticalmultiplexing device shown in FIG. 11;

FIG. 13 is a functional block diagram (1) of a configuration of anoptical demultiplexing device according to a fourth embodiment;

FIG. 14 is a functional block diagram (1) of a configuration of theoptical demultiplexing device according to the fourth embodiment;

FIG. 15 is a time chart for supplementarily explaining a process of abyte processing unit;

FIG. 16 is a time chart concerning an optical signal that the opticaldemultiplexing device shown in FIG. 14 receives;

FIG. 17 is an explanatory diagram (1) for explaining a conventional OTDM(Optical Time Division Multiplex) system; and

FIG. 18 is an explanatory diagram (2) for explaining a conventional OTDM(Optical Time Division Multiplex) system.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Exemplary embodiments of an optical signal demultiplexing deviceaccording to the present invention will be explained below in detailwith reference to the accompanying drawings. Note that the invention isnot limited to the embodiments.

First, characteristics of the present invention are explained withreference to those of a conventional technique. FIG. 17 and FIG. 18 areexplanatory diagrams for explaining the conventional OTDM (Optical TimeDivision Multiplex) system. FIG. 17 is an example that an opticalmultiplexing device 60 multiplexes (time-division multiplexes) opticalsignals transmitted from transmitting stations 10 to 40. Thetransmitting stations 10 to 40 and the optical multiplexing device 60are connected to each other via waveguides 50. A representative exampleof the waveguide 50 is an optical fiber.

The optical multiplexing device 60 includes couplers 61 to 64, amultiplexing unit 65, and an optical-phase-adjustment control unit 66.The couplers 61 to 64 are devices that branch an optical input signalinto two or more outputs. For example, the coupler 61 branches anoptical signal input from the transmitting station 10 into two opticalsignals, inputs one of the optical signals to the multiplexing unit 65,and inputs the other optical signal to the optical-phase-adjustmentcontrol unit 66. The multiplexing unit 65 is a processing unit thatcombines (time-division multiplexes) the optical signals input from thecouplers 61 to 54 with an optical signal input from an FSYN-OHgenerating unit 66 a, and transmits the combined optical signal to anoptical demultiplexing device 70 shown in FIG. 18.

The optical-phase-adjustment control unit 66 is a processing unit thatmonitors phases of the optical signals input from the transmittingstations 10 to 40, and remote controls the phases of the optical signalstransmitted from the transmitting stations 10 to 40. In FIG. 17, thewaveguides 50 connect between the optical-phase-adjustment control unit66 and the transmitting stations 10 to 40, for theoptical-phase-adjustment control unit 66 to control the transmittingstations 10 to 40 (as indicated by arrowheads directed from theoptical-phase-adjustment control unit 66 to the transmitting stations 10to 40). Alternately, this connection can be performed using electricsignals. The optical-phase-adjustment control unit 66 also has theFSYN-OH generating unit 66 a. The FSYN-OH generating unit 66 a is aprocessing unit that generates data (hereinafter, described as overheaddata) such as a synchronization fixed pattern, monitoring-signal linedata, and order wire data, and inputs the generated overhead data to themultiplexing unit 65. The overhead data input to the multiplexing unit65 is combined with other optical signals, and the combined data istransmitted to the optical demultiplexing device 70 shown in FIG. 18.The overhead data is also used to transfer a communication alarm.

FIG. 18 is an example that the optical demultiplexing device 70demultiplexes an optical signal multiplexed by the optical multiplexingdevice 60. The optical demultiplexing device 70 includes an opticalamplifier 71, a branch unit 72, an FSYN synchronization circuit 73, andoptical gates 74 to 77. The optical amplifier 71 is a processing unitthat amplifies an input optical signal, and delivers the amplifiedoptical signal to the branch unit 72.

The branch unit 72 is a processing unit that branches the input opticalsignal into plural optical signals. The branch unit 72 shown in FIG. 18branches the optical signal input from the optical amplifier 71 intofive optical signals, and inputs the branched optical signals to theFSYN synchronization circuit 73, and the optical gates 74 to 77.

The FSYN synchronization circuit 73 is a device that extracts overheaddata contained in the optical signal obtained from the branch unit 72,and changes over between the optical gates 74 following thesynchronization fixed pattern contained in the overhead data. Based onthe change over control performed by the FSYN synchronization circuit73, the optical gates 74 to 77 can demultiplex the optical signalsmultiplexed by the optical multiplexing device 60 shown in FIG. 17.

However, the conventional optical multiplexing device 60 and theconventional optical demultiplexing device 70 shown in FIG. 17 and FIG.18 cannot achieve a network configuration by the OTDM as shown inFIG. 1. FIG. 1 is an explanatory diagram for explaining the networkconfiguration of the OTDM that the conventional optical multiplexingdevice and the conventional optical demultiplexing device cannotachieve.

According to the network configuration shown in FIG. 1, an opticalsignal multiplexed by an optical multiplexing device 60 a is input to anoptical demultiplexing device 70 a, and an optical signal multiplexed byan optical multiplexing device 60 b is input to an opticaldemultiplexing device 70 b. The optical demultiplexing device 70 ademultiplexes the input optical signal, and inputs the demultiplexedoptical signals to optical multiplexing devices 60 c and 60 d. Theoptical demultiplexing device 70 b demultiplexes the input opticalsignal, and inputs the demultiplexed optical signals to the opticalmultiplexing devices 60 c and 60 d.

The optical multiplexing devices 60 c and 60 d cannot OTDM multiplexagain the optical signals obtained from the optical demultiplexingdevices 70 a and 70 b (or other devices), in the state of light. This isbecause the timing concerning multiplexing and demultiplexing by theoptical multiplexing device 60 a and the optical demultiplexing device70 a is different from the timing concerning multiplexing anddemultiplexing by the optical multiplexing device 60 b and the opticaldemultiplexing device 70 b. Consequently, each timing of each opticalsignal cannot be adjusted at the optical level.

In the present invention, the optical demultiplexing device includes asystem that can adjust timings of optical signals transmitted from theoptical multiplexing devices, by increasing a pulse width of the opticalsignals at the optical level (in the present embodiment, an opticaldemultiplexing device is explained as the optical signal demultiplexingdevice).

FIG. 2 is a functional block diagram of a configuration of an opticaldemultiplexing device according to a first embodiment. As shown in FIG.2, this optical demultiplexing device 100 includes an optical amplifier101, a branch unit 102, an FSYN synchronization circuit 103, opticalgates 104 to 107, and a pulse-length increasing unit 108. The opticalamplifier 101, the branch unit 102, the FSYN synchronization circuit103, and the optical gates 104 to 107 are similar to the opticalamplifier 71, the branch unit 72, the FSYN synchronization circuit 73,and the optical gates 74 to 77, respectively, and therefore explanationsthereof will be omitted.

Pulse-length increasing units 108 to 111 are processing units thatincrease pulse widths of the optical signals input from the opticalgates 104 to 107. The pulse-length increasing units 108 to 111 havesimilar configurations. Therefore, the pulse-length increasing unit 108is explained as an example, and the explanation of the pulse-lengthincreasing units 109 to 111 is omitted.

FIG. 3 is a functional block diagram of a configuration of apulse-length increasing unit. As shown in FIG. 3, the pulse-lengthincreasing unit 108 includes an LN waveguide 120, a voltage applyingunit 121, a dispersion fiber 122, an optical amplifier 123, and an SBSgenerating fiber 124.

The LN waveguide 120 includes characteristics of LN (lithium niobate<LiNbO₃>. Specifically, when the voltage applying unit 121 (cyclically)applies a voltage to the LN waveguide 120, a refractive index of the LNwaveguide 120 changes, and the LN waveguide 120 makes the optical signalpassing through the LN waveguide 120 generate chirp. The chirp is aphenomenon that an optical frequency varies with time inside the pulseof the optical signal.

The dispersion fiber 122 increases the pulse width of the optical signalthat generates the chirp. That is, the optical signal that is made togenerate the chirp by the LN waveguide 120 has an increased pulse widthwhen the optical signal passes through the dispersion fiber 122. Theoptical amplifier 123 is a processing unit that amplifies the opticalsignal passing through the dispersion fiber 122.

The SBS generation fiber 124 generates SBS (Stimulated BrillouinScattering) and the like, and flattens the optical signal input from theoptical amplifier 123. The pulse width of the optical signal input fromthe optical gate 104 is increased by passing through the LN waveguide120, the dispersion fiber 122, the optical amplifier 123, and the SBSgeneration fiber 124.

As explained above, the pulse-length increasing units 108 to 111 canincrease, in the state of light, the pulse widths of the optical signalsinput from the optical gates 104 to 107. Therefore, the timings of theoptical signals can be easily adjusted in the state of light. In thenetwork configuration shown in FIG. 1, the optical demultiplexing device100 (the optical demultiplexing device 100 is used in place of theoptical demultiplexing devices 70 a and 70 b) can demultiplex theoptical signals input from the respective optical multiplexing devices,and the optical multiplexing device can OTDM multiplexes the opticalsignals again.

As means for generating chirp, while the pulse-length increasing unithaving the configuration shown in FIG. 3 is most practical, the chirpcan be also generated using a wavelength conversion element, forexample. FIG. 4 and FIG. 5 are functional block diagrams ofconfigurations of a pulse-length increasing unit using the wavelengthconversion element.

The pulse-length increasing unit shown in FIG. 4 includes a wavelengthconversion element 130, a periodic-wavelength-change light source 131, adispersion fiber 132, an optical amplifier 133, and an SBS generationfiber 134. The dispersion fiber 132, the optical amplifier 133, and theSBS generation fiber 134 are similar to the dispersion fiber 122, theoptical amplifier 123, and the SBS generation fiber 124 explained withreference to FIG. 3, respectively, and therefore explanations thereofwill be omitted.

The wavelength conversion element 130 positively uses a gain variationthat becomes the cause of the pattern effect, and converts thewavelength of the input optical signal. By inputting the optical signalfrom the optical gate and inputting light (light of which wavelengthchanges periodically) from the periodic-wavelength-change light source131, the wavelength of the optical signal input from the optical gate isperiodically converted, thereby generating chirp.

The optical signal that generates chirp based on the operation of thewavelength conversion element 130 passes through the dispersion fiber132, the optical amplifier 133, and the SBS generation fiber, therebyincreasing the pulse width.

The pulse-length increasing unit shown in FIG. 5 includes wavelengthconversion elements 140 and 143, periodic-wavelength-change lightsources 141 and 144, and a dispersion fiber 142. The wavelengthconversion elements 140 and 143, the periodic-wavelength-change lightsources 141 and 144, and the dispersion fiber 142 are similar to thewavelength conversion element 130, the periodic-wavelength-change lightsource 131, and the dispersion fiber 132 shown in FIG. 4, respectively.

The pulse-width increasing unit shown in FIG. 5 can increase the pulsewidth of the optical signal input from the optical gate, by repeating attwo times the wavelength conversion, using the wavelength conversionelements 140 and 143.

A state of the optical signal when the OTDM-multiplexed optical signalis input to the optical demultiplexing device 100 is explained. FIG. 6is a time chart of a state that the OTDM-multiplexed optical signal isdemultiplexed by the optical demultiplexing device. As shown in FIG. 6,the optical gates 104 to 107 (the optical gates 104 to 107 correspond toCH1 to CH4, respectively) demultiplex the OTDM-multiplexed opticalsignal, and the pulse-length increasing units 108 to 111 increase thedemultiplexed optical signals.

As described above, in the optical demultiplexing device 100 accordingto the first embodiment, the optical amplifier 101 amplifies the opticalsignal multiplexed by the optical multiplexing device, and the branchunit 102 branches the amplified optical signal, and inputs the branchedoptical signals to the optical gates 104 to 107 and the FSYNsynchronization circuit 103. The FSYN synchronization circuit 103changes over between the optical gates 104 to 107, based on thesynchronization fixed pattern contained in the optical signal, anddemultiplexes the multiplexed optical signal. The pulse-lengthincreasing units 108 to 111 increase the pulse widths of thedemultiplexed optical signals. Therefore, the timings of the opticalsignals can be easily adjusted in the state of light, and the opticalsignals demultiplexed by the optical demultiplexing device 100 can beOTDM multiplexed again.

Next, characteristics of an optical demultiplexing device according to asecond embodiment are explained. The optical demultiplexing device 100according to the first embodiment increases the pulse widths of theoptical signals using the pulse-length increasing units 108 to 111,after the optical signal is branched. On the other hand, in the secondembodiment, the pulse widths of the optical signals are collectivelyincreased.

Because the pulse widths of the optical signals are collectivelyincreased in the second embodiment, parts necessary for the opticaldemultiplexing device can be economized. At the same time, by using theoptical demultiplexing device according to the second embodiment,timings of the optical signals can be adjusted in the state of light,like in the first embodiment, and a high-level process of the electricsignal level can be executed.

Next, a configuration of the optical demultiplexing device according tothe second embodiment is explained. FIG. 7 is a functional block diagramof the configuration of the optical demultiplexing device according tothe second embodiment. As shown in FIG. 7, this optical demultiplexingdevice 200 includes an optical amplifier 201, a branch unit 202, an FSYNsynchronization circuit 203, optical gates 204 to 207, wavelengthconverting units 208 to 210, a wavelength multiplexer 211, apulse-length increasing unit 212, and a wavelength demultiplexer 213.

The optical amplifier 201, the branch unit 202, the FSYN synchronizationcircuit 203, and the optical gates 204 to 207 are similar to the opticalamplifier 101, the branch unit 102, the FSYN synchronization circuit103, and the optical gates 104 to 107, respectively, and thereforeexplanations thereof will be omitted. An optical signal output from theoptical gate 207 shown in FIG. 6 is transmitted to other device (notshown), and an optical signal from other device is input to thewavelength multiplexer 211.

The wavelength converting units 208 to 210 are processing units thatgenerate chirp in the optical signals. The wavelength converting units208 to 210 include the LN waveguide 120 and the voltage applying unit121 shown in FIG. 3, for example. That is, the LN waveguide 120 isperiodically applied with a voltage by the voltage applying unit 121,and a refractive index of the LN waveguide 120 changes. The wavelengthconverting units 208 to 210 make the optical signals passing throughthis LN waveguide 120 generate chirp.

The wavelength multiplexer 211 is a processing unit that multiplexes theoptical signals (optical signals generating the chirp) input from thewavelength converting units 208 to 210. This wavelength multiplexer 211delivers the multiplexed optical signal to the pulse-length increasingunit 212.

The pulse-length increasing unit 212 is a processing unit that increasesthe pulse width of the optical signal input from the wavelengthmultiplexer 211. This pulse-length increasing unit 212 includes thedispersion fiber 122, the optical amplifier 123, and the SBS generationfiber 124 shown in FIG. 3, for example. That is, the dispersion fiber122 increases the pulse width of the optical signal that generateschirp. The optical amplifier 123 amplifies the optical signal. The SBSgeneration fiber 124 adjusts the waveform of the optical signal of whichpulse width is increased. This pulse-length increasing unit 212 canincrease the pulse widths of the optical signals in the state of themultiplexed optical signals.

The wavelength demultiplexer 213 is a processing unit that demultiplexesthe multiplexed optical signal (the pulse width of the optical signal isincreased) input by the pulse-length increasing unit 212. The opticalsignals demultiplexed by the wavelength demultiplexer 213 aretransmitted to the optical multiplexing devices 60 c and 60 d shown inFIG. 1, and are OTDM multiplexed again in the state of light.

As described above, in the optical demultiplexing device 200 accordingto the second embodiment, the optical amplifier 201 amplifies theoptical signal multiplexed by the optical multiplexing device, and thebranch unit 202 branches the amplified optical signal, and inputs thebranched optical signals to the optical gates 204 to 207 and the FSYNsynchronization circuit 203. The optical signals from the optical gates204 to 206 are input to the wavelength converting units 208 to 210. Thewavelength converting units 208 to 210 make the optical signals generatechirp. The wavelength multiplexer 211 multiplexes each optical signal.The pulse-length increasing unit 212 collectively increases the pulsewidth of the multiplexed optical signal, and the wavelengthdemultiplexer 213 demultiplexes the multiplexed optical signal.Therefore, the timings of the optical signals can be easily adjusted atlow cost, and the demultiplexed optical signals can be OTDM multiplexedagain in the state of light.

Next, characteristics of an optical demultiplexing device according to athird embodiment are explained. In demultiplexing the OTDM-multiplexedoptical signal, signal synchronization for demultiplexing an opticalsignal from an ultrafast optical signal needs to be extracted. However,the currently available electric circuit has a slower response speedthan that of the optical signal, and is very hard to extract the signalsynchronization of the OTDM-multiplexed optical signal.

Therefore, the optical demultiplexing device according to the thirdembodiment converts the optical signal into an electric signal, byincreasing the pulse width of the OTDM-multiplexed optical signal, andextracts the signal synchronization for demultiplexing theOTDM-multiplexed optical signal from the electric signal obtained by theconversion. Because the optical signal is converted into the electricsignal by increasing the pulse width, even the currently availabledevice (the electric circuit) having a slow response speed can extractin high precision the signal synchronization for demultiplexing the OTDMsignal.

A configuration of an optical demultiplexing device 300 according to thethird embodiment is explained next. FIG. 8 is a functional block diagramof the configuration of the optical demultiplexing device according tothe third embodiment. As shown in FIG. 8, this optical demultiplexingdevice 300 includes an optical amplifier 301, a branch unit 302, opticalgates 303 to 307, pulse-length increasing units 308 to 312, anopto-electric converter 313, an FSYN synchronization circuit 314, and aphase sweeping unit 315.

The optical amplifier 301, the branch unit 302, and the pulse-lengthincreasing units 308 to 312 are similar to the optical amplifier 101,the branch unit 102, and the pulse-length increasing units 108 to 111shown in FIG. 2, and therefore explanations thereof will be omitted. Theoptical gates 303 to 306 are devices that change over between on andoff, following the instruction of a delay control unit 316, extracts apredetermined optical signal from the optical signal input from thebranch unit 302, and input the extracted optical signal to thepulse-length increasing units 308 to 311. The optical gate 307 is adevice that changes over between on and off, following the instructionof the phase sweeping unit 315, extracts a predetermined optical signalfrom the optical signal input from the optical branch unit 302, andinputs the extracted optical signal to the pulse-length increasing units312.

The opto-electric converter 313 is a processing unit that converts theoptical signal of which pulse width is increased by the pulse-lengthincreasing unit 312, into an electric signal. The opto-electricconverter 313 inputs the converted electric signal to the FSYNsynchronization circuit 314.

The FSYN synchronization circuit 314 is a processing unit that extractsthe signal synchronization of the overhead data contained in theelectric signal obtained from the opto-electric converter 313, anddelivers the extracted signal synchronization to the phase sweeping unit315.

The phase sweeping unit 315 adjusts the timing of a low-speed clock (netclock) input from the outside so that the timing of the signalsynchronization obtained from the FSYN synchronization circuit 314coincides with the timing of the low-speed clock. The phase sweepingunit 315 inputs a clock that becomes the signal synchronizationequivalent to that of the OTDM-multiplexed optical signal, to the delaycontrol unit 316.

The delay control unit 316 is a processing unit that changes overbetween the optical gates 303 to 306 based on the clock input from thephase sweeping unit 315, thereby demultiplexing the OTDM-multiplexedoptical signal. The demultiplexed optical signals are input to thepulse-length increasing units 308 and 311, and the pulse-lengthincreasing units 308 and 311 increase the pulse widths.

As described above, in the optical demultiplexing device 300 accordingto the third embodiment, the pulse-length increasing unit 312 increasesthe pulse width of the optical signal, and the opto-electric converterconverts the optical signal into the electric signal. The FSYNsynchronization circuit 314 extracts the signal synchronization of theoverhead data from the electric signal. The phase sweeping unit 315adjusts the low-speed clock, based on the signal synchronization. Thedelay control unit 316 changes over between the optical gates 303 to306, based on the clock adjusted by the phase sweeping unit 315.Therefore, even when an electric circuit having a slow response speed isused, the OTDM-multiplexed optical signal can be demultiplexed.

Next, characteristics of an optical demultiplexing device according to afourth embodiment are explained. When the optical demultiplexing deviceaccording to the fourth embodiment receives an optical signal that isbyte-interleaved multiplexed by an optical multiplexing device, theoptical demultiplexing device demultiplexes the received optical signalin the state of light. The optical multiplexing device that executes thebyte-interleaved multiplexing is explained first, and then the opticaldemultiplexing device according to the fourth embodiment is explained.

FIG. 9 is a functional block diagram of a configuration of an opticalmultiplexing device that executes a byte-interleaved multiplexing. Asshown in FIG. 9, an optical demultiplexing device 600 includesoptical-variable delay units 601 to 604, couplers 605 to 608, byteprocessing units 609 to 613, optical gates 614 to 618, a multiplexingunit 619, and a phase control unit 620. The couplers 605 to 608 aresimilar to the couplers 61 to 64 shown in FIG. 17, and thereforeexplanations thereof will be omitted.

The optical-variable delay units 601 to 604 are processing units thatdelay optical signals transmitted from the transmitting stations 10 to40, based on control signals transmitted from the phase control unit620. The byte processing units 609 to 613 execute byte-interleavedmultiplexing to optical signals input from the couplers 605 to 608. Thebyte processing units 609 to 613 are similar to each other, andtherefore, the byte processing unit is explained using the byteprocessing unit 609.

The byte processing unit 609 includes a branch CPL 621, waveguides 622to 629, optical gates 630 to 637, and a multiplexing CPL 638. The branchCPL 621 is a device that branches the optical signal input from thecoupler 605, and inputs the branched optical signals to the waveguides622 to 629.

The waveguides 622 to 629 transmit optical signals to the optical gates630 to 637. The waveguides 622 to 629 have mutually different lengths,and therefore, a delay difference occurs in the optical signals passingthrough the waveguides. In the example shown in FIG. 9, waveguides arelong in the order of the waveguides 622, 623, . . . , 629. Therefore,the optical signal passing through the waveguide 622 first reaches theoptical gate 630, and the optical signal passing through the waveguide629 last reaches the optical gate 637.

The optical gates 630 to 637 are devices that perform on and off,following control signals from a control unit (not shown), and extractoptical signals from the waveguides 622 to 629 at a predeterminedtiming. The optical signals output from the optical gates 630 to 637 areinput to the multiplexing CPL 638. The multiplexing CPL 638 is a devicethat combines the optical signals output from the optical gates 630 to637, and inputs the combined optical signal to the optical gate 614.

The optical gates 614 to 618 are devices that execute on and off,following a control signal from the phase control unit 620, and extractoptical signals from the byte processing units 609 to 613 at apredetermined timing. The multiplexing unit 619 is a device thatcombines optical signals input from the optical gates 614 to 618, andoutputs the combined optical signal to the optical demultiplexing device(according to the fourth embodiment).

The phase control unit 620 is a processing unit that controls changeover between the optical gates 614 to 618, controls the optical-variabledelay units 601 to 604, and adjusts the delay amount of the opticalsignals output from the optical-variable delay units 601 to 604. Thephase control unit 620 includes an FSYN-OH generating unit 620 a. ThisFSYN-OH generating unit 620 a is a processing unit that generatesoverhead data, and inputs the generated overhead data to the byteprocessing unit 613.

FIG. 10 is a time chart concerning an optical signal of the opticaldemultiplexing device shown in FIG. 9. The byte processing units 609 to613 execute the byte-interleaved multiplexing to the optical signalsoutput from the optical-variable delay units 601 to 604, respectively.The byte processing unit 613 executes the byte-interleaved multiplexingto the overhead data generated by the FSYN-OH generating unit 620 a. Theoptical signals multiplexed by the byte processing units 609 to 613 areinput to the multiplexing unit 619, and the multiplexing unit 619combines the multiplexed optical signals.

In the optical demultiplexing device 600 shown in FIG. 9, the byteprocessing unit 413 multiplexes the overhead data generated by theFSYN-OH generating unit 620 a. Alternately, as shown in FIG. 11, theoverhead data can be directly input to the optical gate 618, and theoverhead data can be multiplexed by the low-speed signal. Bymultiplexing the overhead signal by the low-speed signal as describedabove, the optical demultiplexing device that becomes the receiving sidecan easily extract the timings.

FIG. 11 is a functional block diagram of a configuration of an opticalsignal device that multiplexes the overhead data by a low-speed signal.Configurations of units are similar to those of the optical multiplexingdevice 600 shown in FIG. 9, and therefore explanations thereof will beomitted. In FIG. 11, the overhead data output from the FSYN-OHgenerating unit 620 a is not input to the byte processing unit, and isinput to the optical gate 618. FIG. 12 is a time chart concerning theoptical signal of the optical multiplexing device shown in FIG. 11. Asshown in FIG. 12, the multiplexing unit 619 combines the overhead databy the low-speed signal.

A configuration of an optical demultiplexing device according to thefourth embodiment is explained next. FIG. 13 and FIG. 14 are functionalblock diagrams of the configuration of the optical demultiplexing deviceaccording to the fourth embodiment. FIG. 13 is an optical demultiplexingdevice corresponding to the optical multiplexing device shown in FIG. 9,and FIG. 14 is an optical demultiplexing device corresponding to theoptical demultiplexing device shown in FIG. 11. The configurations ofthe optical demultiplexing devices are explained below in the order ofFIG. 13 and FIG. 14.

As shown in FIG. 14, this optical demultiplexing device 400 includes anoptical amplifier 401, a branch unit 402, optical gates 403 to 407, bytereceiving units 408 to 412, pulse-length increasing units 413 to 417, anopto-electric converter 418, an FSYN synchronization circuit 419, aphase sweeping unit 420, delay control units 421 and 422, and frequencydividing unit 423.

The optical amplifier 401, the branch unit 402, the optical gates 403 to407, the pulse-length increasing units 413 to 417, the opto-electricconverter 418, the FSYN synchronization circuit 419, the phase sweepingunit 420, and the delay control unit 422 are similar to the opticalamplifier 301, the branch unit 302, the optical gates 303 to 307, thepulse-length increasing units 308 to 312, the opto-electric converter313, the FSYN synchronization circuit 314, the phase sweeping unit 315,and the delay control unit 316, respectively shown in FIG. 8. Therefore,therefore explanations thereof will be omitted.

The byte receiving units 408 to 412 are processing units that receivethe optical signals from the optical gates 403 to 406, and extract andcombine the received optical signals at each predetermined interval. Thebyte receiving units 408 to 412 are similar to each other, andtherefore, the byte receiving unit is explained using the byte receivingunit 408. FIG. 15 is a time chart for supplementarily explaining aprocess of a byte receiving unit.

As shown in FIG. 15, the optical gate 403 extracts optical signals ofD1-1 to D1-8, and the extracted optical signals are input to the bytereceiving unit 408. The byte receiving unit 408 makes a branch CPL 424branch the optical signals D1-1 to D1-8, and inputs the branched opticalsignals to waveguides 425 to 432.

The waveguides 425 to 432 transmit optical signals to optical gates 433to 440. The waveguides 425 to 432 have mutually different lengths, andtherefore, a delay difference occurs in the optical signals passingthrough the waveguides. In the example shown in FIG. 13, waveguides arelong in the order of the waveguides 425, 426, . . . , 432. Therefore,the optical signal passing through the waveguide 425 first reaches theoptical gate 440, and the optical signal passing through the waveguide432 last reaches the optical gate 440.

The optical gates 433 to 440 are devices that perform on and off,following control signals from the delay control unit 421, and extractoptical signals from the waveguides 425 to 432 at a predeterminedtiming. The optical signals output from the optical gates 433 to 440 areinput to a multiplexing CPL 450. The multiplexing CPL 450 is a devicethat combines the optical signals output from the optical gates 433 to440, and inputs the combined optical signal to the pulse-lengthincreasing unit 413.

That is, when the optical signal shown in the upper part of FIG. 15 isinput to the byte receiving unit 408, this optical signal becomes theoptical signal shown in the middle of FIG. 15. When the optical signalfrom the byte receiving unit 408 is input to the pulse-length increasingunit 413, the pulse width of the optical signal is increased, and theoptical signal becomes the one as shown in the lower part in FIG. 15.

The delay control unit 421 is a processing unit that changes overbetween the optical gates held by the byte receiving units 408 to 412 sothat the optical gates are signal-synchronized with the clock input fromthe phase sweeping unit 420. The frequency dividing unit 423 is aprocessing unit that adjusts the clock frequency input from the phasesweeping unit 420 to a specific frequency.

As described above, in the optical demultiplexing device 400 shown inFIG. 13, the byte receiving units 408 to 412 extract thebyte-interleaved multiplexed optical signals, and the pulse-lengthincreasing units 413 to 416 increase the pulse widths of the extractedoptical signals. Therefore, the byte-interleaved multiplexed opticalsignals can be demultiplexed in the state of light.

Next, the optical demultiplexing device that demultiplexes the opticalsignal obtained by multiplexing the overhead data by the low-speedsignal is explained. Configurations of units are similar to those of theoptical demultiplexing device 400 shown in FIG. 13, and thereforeexplanations thereof will be omitted. The optical demultiplexing device400 shown in FIG. 14 is different from the optical demultiplexing deviceshown in FIG. 13 in that the optical demultiplexing device 400 does notinclude the byte receiving unit 412 and the pulse-length increasing unit417.

FIG. 16 is a time chart concerning the optical signal that the opticaldemultiplexing device shown in FIG. 14 receives. The overhead datacontained in the optical signal is multiplexed by the low-speed signal.Therefore, even when the opto-electric converter 418 having a slowresponse speed is used, a synchronization signal of the multiplexedoptical signal can be extracted in high precision, and the multiplexedoptical signal can be demultiplexed in the state of light.

The optical signal demultiplexing device according to the embodimentsreceive an optical signal multiplexed by an optical time-divisionsystem, extracts a synchronization pattern of this optical signal,demultiplexes the optical signal based on the extracted synchronizationpattern, makes the demultiplexed optical signal generate chirp, andpasses the optical signal generating the chirp through a wavelengthdispersion medium, thereby increasing a pulse width of the opticalsignal. Therefore, the optical signal can be adjusted in the state oflight, and a high-level process of an electric signal level can beexecuted.

Although the invention has been described with respect to a specificembodiment for a complete and clear disclosure, the appended claims arenot to be thus limited but are to be construed as embodying allmodifications and alternative constructions that may occur to oneskilled in the art that fairly fall within the basic teaching herein setforth.

1. An optical signal demultiplexing device comprising: a demultiplexingunit that receives an optical signal multiplexed by an opticaltime-division system and a synchronization pattern, and demultiplexesthe optical signal based on the synchronization pattern; and apulse-width increasing unit that makes optical signals demultiplexed bythe demultiplexing unit generate chirp, and increases the pulse widthsof the optical signals generating the chirp by passing the opticalsignals through a wavelength dispersion medium.
 2. The optical signaldemultiplexing device according to claim 1, wherein the pulse-lengthincreasing unit passes the demultiplexed optical signal through an LNwaveguide, and changes a refractive index of the LN waveguide, togenerate the chirp in the optical signals.
 3. The optical signaldemultiplexing device according to claim 1, wherein the pulse-widthincreasing unit generates the chirp in the optical signals in such amanner that the demultiplexed optical signals are passed through awavelength conversion element, the wavelength conversion element isirradiated by light a wavelength of which is periodically changed and onwhich a wavelength conversion is to be performed to change a conversionamount of the wavelength concerning the optical signals.
 4. The opticalsignal demultiplexing device according to claim 3, wherein thepulse-width increasing unit collectively passes the optical signals inwhich the chirp is generated by the wavelength conversion elementthrough the dispersion medium to increase the pulse widths, anddemultiplexes the optical signals that pass through the dispersionmedium.
 5. The optical signal demultiplexing device according to claim1, further comprising: an electric-signal converting unit that increasesthe pulse width of the optical signal and converts the optical signal,whose pulse width is increased, into an electric signal, and ademultiplexing unit that extracts the synchronization pattern of themultiplexed optical signal from the electric signal obtained by aconversion by the electric-signal converting unit, to demultiplex theoptical signal based on the synchronization pattern.
 6. An opticalsignal demultiplexing method comprising: receiving an optical signalmultiplexed by an optical time-division system and a synchronizationpattern, and demultiplexing the optical signal based on thesynchronization pattern; making the demultiplexed optical signalsgenerate chirp; and increasing the pulse widths of the optical signalsgenerating the chirp by passing the optical signals through a wavelengthdispersion medium.
 7. The optical signal demultiplexing method accordingto claim 6, wherein the chirp is generated in the optical signals insuch a manner that the demultiplexed optical signal is passed through anLN waveguide and a refractive index of the LN waveguide is changed. 8.The optical signal demultiplexing method according to claim 6, whereinthe chirp is generated in the optical signals in such a manner that thedemultiplexed optical signals are passed through a wavelength conversionelement, the wavelength conversion element is irradiated by light awavelength of which is periodically changed and on which a wavelengthconversion is to be performed to change a conversion amount of thewavelength concerning the optical signals.
 9. The optical signaldemultiplexing method according to claim 8, wherein the increasingincludes collectively passing the optical signals in which the chirp isgenerated by the wavelength conversion element through the dispersionmedium to increase the pulse widths, and demultiplexes the opticalsignals that pass through the dispersion medium.
 10. The optical signaldemultiplexing method according to claim 6, further comprising:increasing the pulse width of the optical signal and converting theoptical signal, whose pulse width is increased, into an electric signal;and extracting the synchronization pattern of the optical-divisionmultiplexed optical signal from the electric signal, to demultiplex theoptical signal based on the synchronization pattern.